US20090121697A1 - Circuit and method for reducing output noise of regulator - Google Patents
Circuit and method for reducing output noise of regulator Download PDFInfo
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- US20090121697A1 US20090121697A1 US11/937,959 US93795907A US2009121697A1 US 20090121697 A1 US20090121697 A1 US 20090121697A1 US 93795907 A US93795907 A US 93795907A US 2009121697 A1 US2009121697 A1 US 2009121697A1
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/04—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
- H02M3/10—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M3/145—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal
- H02M3/155—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M3/156—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M1/00—Details of apparatus for conversion
- H02M1/0003—Details of control, feedback or regulation circuits
- H02M1/0016—Control circuits providing compensation of output voltage deviations using feedforward of disturbance parameters
- H02M1/0022—Control circuits providing compensation of output voltage deviations using feedforward of disturbance parameters the disturbance parameters being input voltage fluctuations
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S323/00—Electricity: power supply or regulation systems
- Y10S323/901—Starting circuits
Definitions
- the present invention relates to a regulator circuit for generating power supply voltage, and more particularly, to a circuit and method for reducing output noise generated when a pulse width modulation (PWM) mode is started.
- PWM pulse width modulation
- DDC circuits DC-DC converters
- a DDC circuit typically includes either a PWM circuit or a pulse frequency modulation (PFM) circuit or includes both PWM and PFM circuits.
- the PWM circuit adjusts the pulse width of a pulse signal for driving an output transistor in accordance with an output voltage to maintain a constant power supply voltage, which is be supplied to a load.
- the PFM circuit selectively generates a pulse signal in accordance with the output voltage and adjusts the frequency of the pulse signal.
- Other examples of regulator circuits include linear regulators that linearly control an output voltage, such as low dropout (LDO) circuits.
- LDO low dropout
- Japanese Laid-Open Patent Publication Nos. 2005-198484 and 2005-130622 describe regulator circuits that include both linear regulators and switching regulators (DDC circuits).
- FIG. 1 is a schematic block circuit diagram of a conventional regulator circuit (DDC circuit) 100 that includes a PWM circuit 102 and a PFM circuit 104 .
- DDC circuit conventional regulator circuit
- the PWM circuit 102 includes an error amplifier 112 for generating a control voltage V ER in accordance with the difference between an output voltage VO and a reference voltage V REF1 .
- the error amplifier 112 is connected to a PWM generator 114 .
- the PWM generator 114 compares a control voltage V ER with a reference pulse wave (not shown) and generates a pulse signal S PWM having a variable duty cycle.
- the PFM circuit 104 includes a comparator 116 .
- the comparator 116 compares an output voltage VO with a reference pulse wave V REF2 and generates a comparison signal V COMP .
- the comparator 116 is connected to a PFM generator 118 .
- the PFM generator 118 selectively generates a pulse signal S PFM having a substantially constant duty cycle in accordance with the level of the comparison signal V COMP , which is provided from the comparator 116 .
- the PWM circuit 102 and the PFM circuit 104 are connected to a multiplexer 120 .
- the multiplexer 120 selects one of the pulse signal S PWM and the pulse signal S PFM as a drive pulse signal S DRV in response to a mode selection signal S 1 .
- a pre-driver 122 generates drive signals V H and V L for driving output transistors T 1 and T 2 in a complementary manner based on the drive pulse signal S DRV .
- a first terminal of a coil L 1 is connected to a node N 1 between the output transistors T 1 and T 2 .
- a capacitor C 1 is connected between a second terminal of the coil L 1 and ground. The capacitor C 1 smoothes the output voltage VO generated at the second terminal of the coil L 1 .
- the output transistor T 1 When the output transistor T 1 is activated and the output transistor T 2 is deactivated, current corresponding to an input voltage VIN flows from the node N 1 to the coil L 1 . This charges the coil L 1 with energy (current).
- the output transistor T 1 When the output transistor T 1 is deactivated and the output transistor T 2 is activated, the energy accumulated in the coil L 1 is discharged via a loop formed by the output transistor T 2 , the coil L 1 , and the capacitor C 1 . Accordingly, the coil L 1 accumulates energy, the amount of which corresponds to the duty cycle of the drive signal V H (or the drive signal V L ).
- the output voltage VO is controlled in accordance with the amount of accumulated energy.
- FIG. 2 is a schematic waveform chart showing a mode switching operation of the regulator circuit 100 of FIG. 1 .
- the regulator circuit 100 When the regulator circuit 100 is operating in a PFM mode, only the PFM circuit 104 is activated. In this mode, the multiplexer 120 selects the pulse signal S PFM as the drive signal S DRV . As a result, the transistors T 1 and T 2 are driven at a substantially constant duty cycle.
- the PWM circuit 102 is activated (the PFM circuit 104 is deactivated) at timing t 1 . This switches the operation mode of the regulator circuit 100 from the PFM mode to the PWM mode.
- the multiplexer 120 selects the pulse signal S PFM as the drive signal S DRV in response to the mode selection signal S 1 .
- the duty cycle of the pulse signal S PWM is not constant when the PWM circuit 102 starts operating.
- the error amplifier 112 of the PWM circuit 102 usually has an offset resulting from manufacturing variations.
- the reference voltage V REF1 of the error amplifier 112 may be lower than its originally intended target value.
- the PWM circuit 102 generates a pulse signal S PWM that lowers the output voltage VO.
- the drive signals V H and V L drive the output transistors T 1 and T 2 so as to discharge the energy accumulated in the coil L 1 . This results in the output voltage VO including an unintended noise (voltage drop).
- FIG. 3 is a schematic block circuit diagram of a conventional regulator circuit 200 that includes a DDC circuit 202 and an LDO circuit 204 .
- the DDC circuit 202 includes a PWM circuit 210 , a pre-driver 212 , and an output circuit 214 (transistors T 1 and T 2 ).
- the PWM circuit 210 includes an error amplifier 216 and a PWM generator 218 .
- the error amplifier 216 and the PWM generator 218 start operating in response to an enable signal DDCEN.
- the PWM circuit 210 receives an output voltage VO 1 (VO) via a feedback loop FB 1 to control the duty cycle of a pulse signal S PWM in accordance with the level of the received output voltage VO 1 .
- the PWM circuit 210 shown in FIG. 3 operates in the same manner as the PWM circuit 102 shown in FIG. 1 . Thus, the operation of the PWM circuit 210 will not be described in detail.
- the LDO circuit 204 includes an output transistor T 3 , resistors 222 and 224 , and an error amplifier 226 .
- the error amplifier 226 starts operating in response to an enable signal LDOEN.
- the output transistor T 3 receives a control signal V LDO from the error amplifier 226 and generates an output voltage VO 2 (VO) from an input voltage VIN in response to the received controlled voltage V LDO .
- the output voltage VO 2 is supplied from a feedback loop FB 2 to the error amplifier 226 as a feedback via a node N 2 between the resistors 222 and 224 .
- the error amplifier 226 compares a reference voltage V REF with the feedback voltage of the output voltage VO 2 . Based on the comparison result, the error amplifier 226 generates the control voltage V LDO to compensate for fluctuations in the output voltage VO 2 .
- the regulator circuit 200 selectively operates the DDC circuit 202 (or the PWM circuit 210 ) and the LDO circuit 204 in accordance with the enable signals DDCEN and LDOEN and generates the output voltage VO in either the PWM mode or the LDO mode.
- FIG. 4 is a schematic waveform chart showing a mode switching operation of the regulator circuit 200 of FIG. 3 .
- the PWM circuit 210 When the LDO circuit 204 is activated in the LDO mode based on a high (H) level enable signal LDOEN, the PWM circuit 210 is deactivated based on a low (L) level enable signal DDCEN. In this case, the regulator circuit 200 outputs the output voltage VO 2 that is generated by the LDO circuit 204 as the output voltage VO.
- the PWM circuit 210 starts operating in response to an H level enable signal DDCEN at timing t 1 . This switches the operation mode of the regulator circuit 200 from the LDO mode to the PWM mode.
- the coil L 1 which is connected to the node N 1 of the DDC circuit 202 , has not been charged with current energy. Further, the error amplifier 216 of the PWM circuit 102 has an offset in the same manner as the error amplifier shown in FIG. 1 . Thus, the duty cycle of the pulse signal S PWM is lower than its expected value (the duty increases gradually from zero). As a result, the energy stored in the coil L 1 and the offset of the error amplifier 216 may cause the output voltage VO to include unintended noise (voltage drop).
- FIG. 1 is a schematic block circuit diagram of a conventional regulator circuit (DDC circuit) that includes a PWM circuit and a PFM circuit;
- DDC circuit conventional regulator circuit
- FIG. 2 is a schematic waveform chart showing a drive sequence of the regulator circuit of FIG. 1 when the operation mode switches from a PFM mode to a PWM mode;
- FIG. 3 is a schematic block circuit diagram of a conventional regulator circuit that includes a DDC circuit (PWM circuit) and an LDO circuit;
- PWM circuit DDC circuit
- LDO circuit LDO circuit
- FIG. 4 is a schematic waveform chart showing a drive sequence of the regulator circuit of FIG. 3 when the operation mode switches from an LDO mode to a PWM mode;
- FIG. 5 is a schematic block circuit diagram of a regulator circuit (DDC circuit) that includes a PWM circuit and a PFM circuit according to a first embodiment of the present invention
- FIG. 6 is a schematic block circuit diagram of another PWM circuit (another feed forward circuit) according to the present invention.
- FIG. 7 is a schematic waveform chart showing a drive sequence of the regulator circuit of FIG. 5 when the operation mode switches from a PFM mode to a PWM mode;
- FIG. 8 is a schematic block circuit diagram of a regulator circuit that includes a DDC circuit and an LDO circuit according to a second embodiment of the present invention.
- FIG. 9A is a schematic waveform chart showing a drive sequence of the regulator circuit of FIG. 8 when the duty cycle is controlled with an error amplifier and a feed forward circuit before the PWM mode is started;
- FIG. 9B is a schematic waveform chart showing a drive sequence of the regulator circuit of FIG. 8 when the duty cycle is controlled with only the feed forward circuit before the PWM mode is started.
- the present invention provides a circuit and a method for reducing output noise generated when a PWM mode is started.
- the regulator circuit includes a pulse width modulation circuit for generating a first pulse signal having a duty cycle that is in accordance with the output voltage.
- a drive circuit generates the output voltage from the input voltage in response to the first pulse signal provided from the pulse width modulation circuit.
- a feed forward circuit controls the pulse width modulation circuit to generate the first pulse signal having a duty cycle that maintains the output voltage at a desired level before the pulse width modulation circuit provides the first pulse signal to the drive circuit.
- the regulator circuit includes a pulse width modulation circuit for controlling the output voltage with a first pulse signal, a pulse frequency modulation circuit for controlling the output voltage with a second pulse signal, and a feed forward circuit for controlling a duty cycle of the first pulse signal.
- the method includes activating the pulse frequency modulation circuit, controlling the output voltage with the second pulse signal, activating the feed forward circuit and the pulse width modulation circuit when the pulse frequency modulation circuit is operating, generating the first pulse signal with at least the feed forward circuit until operation of the pulse width modulation circuit is stabilized, and deactivating the pulse frequency modulation circuit after the operation of the pulse width modulation circuit is stabilized.
- a further aspect of the present invention is a method for driving a regulator circuit that generates an output voltage from an input voltage.
- the regulator circuit includes a low dropout circuit for linearly controlling the output voltage, a pulse width modulation circuit for controlling the output voltage with a first pulse signal, and a feed forward circuit for controlling a duty cycle of the first pulse signal.
- the method includes activating the low dropout circuit, controlling the output voltage with the low dropout circuit, activating the feed forward circuit and the pulse width modulation circuit when the low dropout circuit is operating, generating the first pulse signal with at least the feed forward circuit until operation of the pulse width modulation circuit is stabilized, and deactivating the low dropout circuit after operation of the pulse width modulation circuit is stabilized.
- FIG. 5 is a schematic block circuit diagram of a regulator circuit 10 according to a first embodiment of the present invention.
- the regulator circuit 10 is a DDC circuit including a PFM circuit 12 , a PWM circuit 14 , a multiplexer (MUX) 16 , a pre-driver 18 , and an output circuit 20 .
- the output circuit 20 includes first and second transistors T 1 and T 2 .
- the first transistor T 1 is formed by a P-channel MOS (metal oxide semiconductor) transistor
- the second transistor T 2 is formed by an N-channel MOS transistor.
- the pre-driver 18 and the output circuit 20 form a drive circuit 19 .
- a coil (choke coil) L 1 has a first terminal, which is connected to a node N 1 between the first and second transistors T 1 and T 2 , and a second terminal, which is connected to ground via a capacitor C 1 .
- the capacitor C 1 is a smoothing capacitor for smoothing output voltage VO that is generated at the second terminal of the coil L 1 .
- the PWM circuit 14 includes an error amplifier 26 , a feed forward circuit (hereafter referred to as “FF circuit”) 28 , a signal processing circuit 30 , and a PWM generator 32 .
- the signal processing circuit 30 is connected to the error amplifier 26 and the FF circuit 28 .
- the PWM generator 32 is connected to the signal processing circuit 30 .
- the signal processing circuit 30 and the PWM generator 32 are activated in response to an enable signal PWMEN.
- the PWM circuit 14 compares the output voltage VO with a first reference voltage V REF1 to generate a first pulse signal S PWM having a duty cycle determined in accordance with the comparison result.
- the structure of the PWM circuit 14 will now be described in detail.
- the error amplifier 26 is supplied with the output voltage VO and the first reference voltage V REF1 .
- the first reference voltage V REF1 corresponds to a target value of the output voltage VO.
- the error amplifier 26 amplifies the voltage difference between the output voltage VO and the first reference voltage V REF1 to generate a control voltage V ER for adjusting the duty cycle of the first pulse signal S PWM . More specifically, when the output voltage VO is lower than the first reference voltage V REF1 , the error amplifier 26 increases the control voltage V ER in accordance with the voltage difference between the output voltage VO and the first reference voltage V REF1 .
- the error amplifier 26 decreases the control voltage V ER in accordance with the voltage difference between the output voltage VO and the first reference voltage V REF1 . Accordingly, the error amplifier 26 generates the control voltage V ER so that the output voltage VO becomes equal to the first reference voltage V REF1 .
- the FF circuit 28 controls the PWM circuit 14 to generate the first pulse signal S PWM , which has a duty cycle that maintains the output voltage VO at a predetermined level (or the target value), before the PWM circuit 14 provides the first pulse signal S PWM to the drive circuit 19 .
- the FF circuit 28 adjusts the duty cycle of the first pulse signal S PWM , which is generated by the PWM circuit 14 , in a manner independent from the control voltage V ER , which is generated by the error amplifier 26 . More specifically, the FF circuit 28 generates a feed forward voltage V FF for adjusting the duty cycle of the first pulse signal S PWM using the output voltage VO and input voltage VIN.
- the first reference voltage V REF1 corresponding to the target value of the output voltage VO may be used instead of the output voltage VO.
- the FF circuit 28 is formed by a divider that calculates the duty cycle DTY using equation (2).
- the divider (FF circuit 28 ) divides the output voltage VO by the input voltage VIN and generates the quotient (i.e., duty cycle DTY) as the feed forward voltage V FF .
- the divider may have any structure.
- the signal processing circuit 30 is supplied with the control voltage V ER from the error amplifier 26 and the feed forward voltage V FF from the FF circuit 28 and provided with a control signal S CONT .
- the signal processing circuit 30 synthesizes the control voltage V ER and the feed forward voltage V FF at a predetermined ratio (for example 1:1) in response to the control signal S CONT to generate a duty control voltage V DTY .
- the feed forward voltage V FF and the control voltage V ER may be synthesized at any ratio.
- the voltages V FF and V ER may be weighted with a predetermined coefficient before being synthesized with each other.
- the control signal S CONT is asserted simultaneously as the enable signal PWMEN. In the first embodiment, the enable signal PWMEN may be used as the control signal S CONT .
- the duty control voltage V DTY is supplied to the PWM generator 32 .
- the PWM generator 32 compares the duty control signal V DTY with a reference pulse wave (not shown in FIG. 5 ) to generate the first pulse signal S PWM .
- the PFM circuit 12 includes a comparator 22 and a PFM generator 24 , which is connected to the comparator 22 .
- the comparator 22 and the PFM generator 24 are activated based on an enable signal, which is not shown.
- the PFM circuit 12 has the same structure as the PFM circuit 104 shown in FIG. 1 .
- the comparator 22 compares the output voltage VO with a second reference voltage V REF2 and generates a comparison signal S COMP .
- the PFM generator 24 selectively generates a second pulse signal S PFM having a substantially constant duty cycle that is determined in accordance with the level of the comparison signal S COMP , which is provided from the comparator 22 .
- the PFM generator 24 generates the second pulse signal S PFM only when the output voltage VO is lower than the second reference voltage V REF2 .
- the multiplexer 16 is provided with the first pulse signal S PWM , the second pulse signal S PFM , and a mode selection signal S SELECT .
- the multiplexer 16 selects one of the first and second pulse signals S PWM and S PFM as a drive pulse signal S DRV . More specifically, the mode selection signal S SELECT is set at a first level in the PWM mode. The multiplexer 16 selects the first pulse signal S PWM in response to the mode selection signal S SELECT with the first level. The mode selection signal S SELECT is set at a second level in the PFM mode. The multiplexer 16 selects the second pulse signal S PFM in response to the mode selection signal S SELECT with the second level.
- the mode selection signal S SELECT shifts from the second level to the first level based on the enable signal PWMEN.
- the mode selection signal S SELECT shifts from the second level to the first level when a predetermined time elapses after assertion of the enable signal PWMEN.
- the operation mode switches from the PFM mode to the PWM mode when the predetermined time elapses after the PWM circuit 14 is activated.
- the operation mode switches from the PFM mode to the PWM mode when the duty cycle of the first pulse signal S PWM is stabilized. In other words, the PWM mode is started only after the duty cycle of the first pulse signal S PWM is stabilized. This prevents an unstable drive pulse signal S DRV from being generated when the PWM mode is started.
- the drive pulse signal S DRV which is output from the multiplexer 16 , is provided to the pre-driver 18 of the drive circuit 19 .
- the pre-driver 18 generates the first and second drive signals V H and V L for driving the first and second transistors T 1 and T 2 in a complementary manner based on the drive pulse signal S DRV .
- the first drive signal V H is provided to the gate of the first transistor (PMOS transistor) T 1 .
- the second drive signal V L is provided to the gate of the second transistor T 2 (NMOS transistor).
- the source of the first transistor T 1 is connected to the input voltage VIN, and the drain of the first transistor T 1 is connected to the drain of the second transistor T 2 .
- the source of the second transistor T 2 is connected to ground.
- the current corresponding to the input voltage VIN flows from the node N 1 between the transistors T 1 and T 2 through the coil L 1 .
- the first transistor T 1 is deactivated and the second transistor T 2 is activated, the energy accumulated in the coil L 1 is discharged via a loop formed by the second transistor T 2 , the coil L 1 , and the capacitor C 1 . Accordingly, the coil L 1 accumulates energy, the amount of which corresponds to the duty cycle of the drive signal V H (or the drive signal V L ).
- the output voltage VO is changed in accordance with the amount of accumulated energy.
- FIG. 7 is a schematic waveform chart showing a drive sequence of the regulator circuit 10 of FIG. 5 when the operation mode switches from the PFM mode to the PWM mode.
- the regulator circuit 10 operates in the PFM mode before timing t 1 . In this mode, only the PFM circuit 12 is activated, and the multiplexer 16 selects the second pulse signal S PFM as the drive pulse S DRV . As a result, the first and second transistors T 1 and T 2 are driven at a substantially constant duty cycle.
- the PWM circuit 14 is activated based on the enable signal PWMEN at timing t 1 .
- the PWM circuit 14 starts operating and generates the first pulse signal S PWM with the control voltage V ER , which is generated by the error amplifier 26 , and the feed forward voltage V FF , which is generated by the FF circuit 28 .
- the mode selection signal S SELECT is maintained at the second level, which corresponds to the PFM mode.
- the drive pulse signal S DRV which is output from the multiplexer 16 , is maintained as the second pulse signal S PFM .
- the regulator circuit 10 continues operating in the PFM mode.
- the mode selection signal S SELECT shifts from the second level to the first level at timing t 2 .
- the multiplexer 16 selects the first pulse signal S PWM as the drive pulse signal S DRV in response to the mode selection signal S SELECT , which has the first level. This switches the operation mode of the regulator circuit 10 from the PFM mode to the PWM mode.
- the operation mode switches from the PFM mode to the PWM mode when the duty cycle of the first pulse signal S PWM is stabilized.
- the PWM mode is started (timing t 2 )
- the first and second transistors T 1 and T 2 are driven based on the stabilized first pulse signal S PWM . This prevents the output voltage VO from including unintended noise (voltage drop).
- FIG. 6 is a schematic block circuit diagram of another PWM circuit 40 according to the present invention.
- the PWM circuit 40 may be used in lieu of the PWM circuit 14 in the regulator circuit 10 shown in FIG. 5 .
- the PWM circuit 40 includes an error amplifier 26 , a signal processing circuit 30 , a switch circuit 42 , a filter circuit 44 , an integration circuit 46 , an oscillation circuit 47 , and a comparison circuit 48 .
- the oscillation circuit 47 and the comparison circuit 48 form a PWM generator.
- the switch circuit 42 , the filter circuit 44 , the integration circuit 46 , the oscillation circuit 47 , and the comparison circuit 48 form a feed forward circuit (FF circuit) 49 .
- the error amplifier 26 , the signal processing circuit 30 , the oscillation circuit 47 , and the comparison circuit 48 are activated based on an enable signal PWMEN.
- the oscillation circuit 47 generates a sawtooth reference pulse wave V W and provides an inversion input terminal of the comparison circuit 48 with the reference pulse signal V W .
- a non-inversion input terminal of the comparison circuit 48 is supplied with the duty control voltage V DTY , which is generated by the signal processing circuit 30 .
- the comparison circuit 48 compares the duty control signal V DTY with the reference pulse wave V W and changes the duty cycle of the first pulse signal S PWM in accordance with the comparison result. As a result, when the duty control voltage V DTY fluctuates, the duty cycle of the first pulse signal S PWM changes accordingly.
- the switch circuit 42 includes switch elements SW 1 and SW 2 and an inversion circuit 52 .
- the switch elements SW 1 and SW 2 are connected to the comparison circuit 48 .
- the inversion circuit 52 is connected to a node NA between the switch elements SW 1 and SW 2 .
- the switch elements SW 1 and SW 2 are driven in a complementary manner based on the first pulse signal S PWM .
- the switch element SW 1 may be formed by a P-channel MOS transistor
- the switch element SW 2 may be formed by an N-channel MOS transistor.
- the inversion circuit 52 generates an inverted signal that is obtained by inverting a signal output at the node NA based on the input voltage VIN.
- the switch circuit 42 generates a control pulse signal V 1 having the same polarity (the same pulse width) as the first pulse signal S PWM .
- the switch circuit 42 is not limited to the structure shown in FIG. 6 and may have any structure.
- the switch circuit 42 may generate a pulse signal of which polarity is opposite to the polarity of the first pulse signal S PWM .
- the filter circuit 44 is a low-pass filter that includes a resistor R 1 and a capacitor C 2 .
- the filter circuit 44 eliminates high-frequency elements from the control pulse signal V 1 , which is provided from the switch circuit 42 , and generates an adjustment voltage V 2 , which is substantially a DC voltage.
- the adjustment voltage V 2 is approximated by VIN*DTY (i.e., right-hand side of equation (1)), in which the duty cycle of the first pulse signal S PWM is represented by DTY.
- the integration circuit 46 includes an amplifier 54 , a resistor R 2 , and a capacitor C 3 .
- the resistor R 2 is connected to an inversion input terminal of the amplifier 54 .
- the capacitor C 3 is connected between the inversion input terminal and output terminal of the amplifier 54 .
- the inversion input terminal of the amplifier 54 is supplied with an output voltage VO of the regulator circuit 10 via the resistor R 2 .
- a target value of the output voltage VO may be used instead of the output voltage VO.
- a non-inversion input terminal of the amplifier 54 is supplied with an adjustment voltage V 2 1 which is supplied from the filter circuit 44 .
- the amplifier 54 compares the adjustment voltage V 2 with the output voltage VO.
- the amplifier 54 amplifies the difference between the voltages V 2 and VO in accordance with the comparison result and generates a feed forward voltage V FF .
- the feed forward voltage V FF is supplied to the signal processing circuit 30 .
- the signal processing circuit 30 then synthesizes the feed forward voltage V FF with the control voltage V ER , which is generated by the feed forward voltage V FF , to generate a duty control voltage V DTY .
- the FF circuit 49 generates the feed forward voltage V FF from the input voltage VIN and the output voltage VO in accordance with the first pulse signal S PWM , which is provided as a feedback via a loop 50 that connects the comparison circuit 48 (pulse generator) and the switch circuit 42 .
- the FF circuit 49 generates the feed forward voltage V FF in a manner that the adjustment voltage V 2 (i.e., the right-hand side of equation (1), or “VIN*DTY”) becomes equal to the output voltage VO (i.e., the left-hand side of equation (1)).
- the FF circuit 49 generates the feed forward voltage V FF more accurately than the FF circuit 28 (divider) shown in FIG. 5 .
- the FF circuit 49 does not necessarily have to use the duty control voltage V DTY , which is supplied from the signal processing circuit 30 .
- the FF circuit 49 may include another PWM comparison circuit that has the same structure as the comparison circuit 48 .
- the PWM comparison circuit receives the feed forward voltage V FF directly from the integration circuit 46 , compares the feed forward voltage V FF with the reference pulse wave V W , and generates the first pulse signal S PWM .
- the FF circuit 49 generates the feed forward voltage V FF in a manner independent from the control voltage V ER , which is generated by the error amplifier 26 . This quickly stabilizes the duty cycle of the first pulse signal S PWM .
- the signal processing circuit 30 shown in FIG. 6 may select the feed forward voltage V FF as the duty control voltage V DTY .
- the regulator circuit 10 of the first embodiment has the advantages described below.
- the PWM circuit 14 starts operating before the operation mode switches from the PFM mode to the PWM mode.
- the PWM circuit 14 generates the first pulse signal S PWM with the error amplifier 26 and the FF circuit 28 before the PWM mode is started.
- the PWM mode is then started after the duty cycle of the first pulse signal S PWM is stabilized.
- the drive circuit 19 is then driven based on the first pulse signal S PWM . This prevents the output voltage VO from including unintended noise (voltage drop) that is generated when the PWM mode is started.
- the PWM circuit 14 generates the first pulse signal S PWM with the error amplifier 26 and the FF circuit 28 . This stabilizes the duty cycle of the first pulse signal S PWM more quickly than when the error amplifier 26 is used solely. As a result, the operation mode quickly switches from the PFM mode to the PWM.
- the PWM circuit 14 Before the PFM mode is started, the PWM circuit 14 is driven when the PFM circuit 12 is still being driven. However, the drive circuit 19 is actually driven by the second pulse signal S PFM until the PWM mode is started. This prevents the first pulse signal S PWM from destabilizing the operation of the regulator circuit 10 in the PFM mode.
- the FF circuit 28 generates the feed forward voltage V FF with the input voltage VIN and the output voltage VO (generated by the PFM circuit 12 ). Thus, the FF circuit 28 controls the duty cycle in a manner independent from the control voltage V ER , which is generated by the error amplifier 26 .
- the PWM generator 32 generates the first pulse signal S PWM with the duty control voltage V DTY , which is generated from the control voltage V ER and the feed forward voltage V FF . This accurately control the duty cycle of the first pulse signal S PWM with the control voltage V ER and quickly stabilizes the feed forward voltage V FF in the PWM mode.
- the FF circuit 49 in FIG. 6 feedback controls the feed forward voltage V FF with the first pulse signal S PWM .
- the FF circuit 49 generates the feed forward voltage V FF more accurately than the FF circuit 28 ( FIG. 5 ).
- FIG. 8 is a schematic block circuit diagram of a regulator circuit 60 according to a second embodiment of the present invention.
- the regulator circuit 60 of the second embodiment includes a DDC circuit 62 and an LDO circuit 64 .
- the DDC circuit 62 includes a PWM circuit 72 , a pre-driver 74 , and an output circuit 20 .
- the PWM circuit 72 is formed by either the PWM circuit 14 in FIG. 5 or the PWM circuit 40 in FIG. 6 .
- the pre-driver 74 and the output circuit 20 form a drive circuit of the present invention.
- the drive circuit operates in the same manner as the drive circuit 19 of FIG. 5 .
- the PWM circuit 72 receives an output voltage VO 1 (VO) via a feedback loop FB 1 and controls the duty cycle of a first pulse signal S PWM in accordance with the level of the received output voltage VO 1 .
- the pre-driver 74 generates drive signals V H and V L based on the first pulse signal S PWM .
- Transistors T 1 and T 2 are driven in a complementary manner based on the drive signals V H and V L .
- a coil L 1 accumulates current energy (current) based on the driving of the transistors T 1 and T 2 .
- the output voltage VO 1 is controlled in accordance with the amount of accumulated energy.
- the PWM circuit 72 is activated based on an enable signal PWMEN.
- the pre-driver 74 is activated based on an enable signal DRVEN.
- the enable signal DRVEN is associated with the enable signal PWMEN. More specifically, the enable signal DRVEN is asserted when a predetermined time elapses after the enable signal PWMEN is asserted.
- the pre-driver 74 is activated when the predetermined time elapses after the PWM circuit 72 is activated.
- the pre-driver 74 is activated when the duty cycle of the first pulse signal S PWM , which is generated by the PWM circuit 72 , stabilizes.
- the PWM mode is started only after the duty cycle of the first pulse signal S PWM is stabilized. This prevents unstable drive signals V H and V L from being generated when the PWM mode is started.
- the LDO circuit 64 includes a transistor T 3 , resistors 82 and 84 , and an error amplifier 86 .
- the error amplifier 86 starts operating in response to an enable signal LDOEN.
- the transistor T 3 receives a control signal V LDO from the error amplifier 86 and generates an output voltage VO 2 (VO) from an input voltage VIN in response to the received control voltage V LDO .
- the output voltage VO 2 is supplied as a feedback from the feedback loop FB 2 to the error amplifier 86 via a node N 2 between the resistors 82 and 84 .
- the error amplifier 86 compares a reference voltage V REF3 with a feedback voltage of the output voltage VO 2 to generate a control voltage V LDO , which compensates for fluctuations in the output voltage VO 2 based on the comparison result.
- the regulator circuit 60 selectively operates the DDC circuit 62 (i.e., the PWM circuit 72 ) and the LDO circuit 64 in accordance with the enable signals PWMEN and LDOEN to generate the output voltage VO in either the PWM mode or the LDO mode.
- FIG. 9A is a schematic waveform chart showing a switching operation of the regulator circuit 60 shown in FIG. 8 from the LDO mode to the PWM mode.
- the PWM circuit 72 When the LDO circuit 64 is activated based on an H level enable signal LDOEN in the LDO mode, the PWM circuit 72 is deactivated based on an L level enable signal PWMEN. Thus, the regulator circuit 60 outputs the output voltage VO 2 , which is generated by the LDO circuit 64 , as the output voltage VO.
- the enable signal PWMEN shifts to an H level at timing t 11 .
- the PWM circuit 72 starts operating in response to the H level enable signal PWMEN and generates a first pulse signal S PWM based on the control signal V ER , which is generated by the error amplifier 26 , and the feed forward voltage V FF , which is generated by the FF circuit 28 (or the FF circuit 49 ).
- V ER the control signal
- V FF feed forward voltage
- the first pulse signal S PWM increases gradually as the PWM circuit 72 operates.
- the enable signal DRVEN is maintained at an L level (the pre-driver 74 is maintained to be deactivated).
- the regulator circuit 60 continues operating in the LDO mode.
- the enable signal LDOEN shifts to an L level and the enable signal DRVEN shifts to an H level. This deactivates the LDO circuit 64 and activates the pre-driver 74 of the DDC circuit 62 .
- the enable signal PWMEN is maintained at an H level.
- the PWM circuit 72 continues operating. As a result, the operation mode of the regulator circuit 60 switches from the LDO mode to the PWM mode.
- the pre-driver 74 is activated (or the operation mode switches from the LDO mode to the PWM mode) when the duty cycle of the first pulse signal S PWM is stabilized.
- the PWM mode is started (at timing t 12 )
- the first and second transistors T 1 and T 2 are driven based on the stabilized first pulse signal S PWM . This significantly reduces output noise (voltage drop) when the LDO mode is switched to the PWM mode.
- the regulator circuit 60 of the second embodiment has the advantages described below.
- the PWM circuit 72 starts operating before the operation mode switches from the LDO mode to the PWM mode.
- the PWM circuit 72 generates the first pulse signal S PWM with the error amplifier 26 and the FF circuit 28 (FF circuit 49 ) before the PWM mode is started.
- the PWM mode is started based on the enable signal DRVEN after the duty cycle of the firs pulse signal S PWM is stabilized.
- the drive circuit (the pre-driver 74 and the output circuit 20 ) is then driven based on the first pulse signal S PWM . This significantly reduces output noise generated when the LDO mode is switched to the PWM mode.
- the PWM circuit 72 generates the first pulse signal S PWM with the error amplifier 26 and the FF circuit 28 (or the FF circuit 49 ). This stabilizes the duty cycle of the first pulse signal S PWM more quickly than when the error amplifier 26 is used solely. Accordingly, the operation mode is quickly switched from the LDO mode to the PWM mode.
- the PWM circuit 72 is driven when the LDO circuit 64 is still being driven. However, the DDC circuit 62 does not operate (only the PWM circuit 72 operates) until the enable signal DRVEN activates the pre-driver 74 . This prevents the first pulse signal S PWM from destabilizing the operation of the regulator circuit 60 in the LDO mode.
- FIG. 9B is a schematic waveform chart showing a drive sequence of the regulator circuit 60 of FIG. 8 when the duty cycle is controlled by only the FF circuit ( 28 or 49 ) before the PWM mode is started.
- the regulator circuit 60 operates in the LDO mode before timing t 11 .
- the PWM circuit 72 starts operating in response to an H level enable signal PWMEN.
- the PWM circuit 72 generates a first pulse signal S PWM from only the feed forward voltage V FF .
- the signal processing circuit 30 selects the feed forward voltage V FF as the duty control voltage V DTY in response to the control signal S CONT having the first level (refer to FIG. 5 or FIG. 6 ).
- the pre-driver 74 is activated based on the enable signal DRVEN at timing t 13 , and the PWM mode is started.
- the PWM circuit 72 When a predetermined time elapses after the PWM mode is started, the PWM circuit 72 generates a first pulse signal S PWM with the error amplifier 26 and the FF circuit 28 or 49 (or generates a first pulse signal S PWM with only the error amplifier 26 ). More specifically, the signal processing circuit 30 selects a signal generated by synthesizing the control voltage V ER and the feed forward voltage V FF as the duty control voltage V DTY (or selects the control voltage V ER as the duty control voltage V DTY ) in response to the control signal S CONT having the second level. This generates the first pulse signal S PWM in a manner independent from the output of the error amplifier 26 before the PWM mode is started. Thus, the operation mode is switched more quickly from the LDO mode to the PWM mode (during t 11 to t 13 ) than the control in FIG. 9A .
- the FF circuit 28 may be separate from the PWM circuit 14 .
- the FF circuit 49 may be separate from the PWM circuit 40 .
- the present invention is also applicable to a regulator circuit that operates in one of an LDO mode, a PFM mode, and a PWM mode.
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Abstract
Description
- The present invention relates to a regulator circuit for generating power supply voltage, and more particularly, to a circuit and method for reducing output noise generated when a pulse width modulation (PWM) mode is started.
- In the prior art, DDC circuits (DC-DC converters) are known as regulator circuits. A DDC circuit typically includes either a PWM circuit or a pulse frequency modulation (PFM) circuit or includes both PWM and PFM circuits. The PWM circuit adjusts the pulse width of a pulse signal for driving an output transistor in accordance with an output voltage to maintain a constant power supply voltage, which is be supplied to a load. The PFM circuit selectively generates a pulse signal in accordance with the output voltage and adjusts the frequency of the pulse signal. Other examples of regulator circuits include linear regulators that linearly control an output voltage, such as low dropout (LDO) circuits. For example, Japanese Laid-Open Patent Publication Nos. 2005-198484 and 2005-130622 describe regulator circuits that include both linear regulators and switching regulators (DDC circuits).
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FIG. 1 is a schematic block circuit diagram of a conventional regulator circuit (DDC circuit) 100 that includes aPWM circuit 102 and aPFM circuit 104. - The
PWM circuit 102 includes anerror amplifier 112 for generating a control voltage VER in accordance with the difference between an output voltage VO and a reference voltage VREF1. Theerror amplifier 112 is connected to aPWM generator 114. ThePWM generator 114 compares a control voltage VER with a reference pulse wave (not shown) and generates a pulse signal SPWM having a variable duty cycle. - The
PFM circuit 104 includes acomparator 116. Thecomparator 116 compares an output voltage VO with a reference pulse wave VREF2 and generates a comparison signal VCOMP. Thecomparator 116 is connected to aPFM generator 118. ThePFM generator 118 selectively generates a pulse signal SPFM having a substantially constant duty cycle in accordance with the level of the comparison signal VCOMP, which is provided from thecomparator 116. - The
PWM circuit 102 and thePFM circuit 104 are connected to amultiplexer 120. Themultiplexer 120 selects one of the pulse signal SPWM and the pulse signal SPFM as a drive pulse signal SDRV in response to a mode selection signal S1. A pre-driver 122 generates drive signals VH and VL for driving output transistors T1 and T2 in a complementary manner based on the drive pulse signal SDRV. - A first terminal of a coil L1 is connected to a node N1 between the output transistors T1 and T2. A capacitor C1 is connected between a second terminal of the coil L1 and ground. The capacitor C1 smoothes the output voltage VO generated at the second terminal of the coil L1.
- When the output transistor T1 is activated and the output transistor T2 is deactivated, current corresponding to an input voltage VIN flows from the node N1 to the coil L1. This charges the coil L1 with energy (current). When the output transistor T1 is deactivated and the output transistor T2 is activated, the energy accumulated in the coil L1 is discharged via a loop formed by the output transistor T2, the coil L1, and the capacitor C1. Accordingly, the coil L1 accumulates energy, the amount of which corresponds to the duty cycle of the drive signal VH (or the drive signal VL). The output voltage VO is controlled in accordance with the amount of accumulated energy.
-
FIG. 2 is a schematic waveform chart showing a mode switching operation of theregulator circuit 100 ofFIG. 1 . - When the
regulator circuit 100 is operating in a PFM mode, only thePFM circuit 104 is activated. In this mode, themultiplexer 120 selects the pulse signal SPFM as the drive signal SDRV. As a result, the transistors T1 and T2 are driven at a substantially constant duty cycle. - Subsequently, the
PWM circuit 102 is activated (thePFM circuit 104 is deactivated) at timing t1. This switches the operation mode of theregulator circuit 100 from the PFM mode to the PWM mode. Themultiplexer 120 selects the pulse signal SPFM as the drive signal SDRV in response to the mode selection signal S1. - The duty cycle of the pulse signal SPWM is not constant when the
PWM circuit 102 starts operating. Theerror amplifier 112 of thePWM circuit 102 usually has an offset resulting from manufacturing variations. For example, the reference voltage VREF1 of theerror amplifier 112 may be lower than its originally intended target value. In this case, thePWM circuit 102 generates a pulse signal SPWM that lowers the output voltage VO. More specifically, the drive signals VH and VL drive the output transistors T1 and T2 so as to discharge the energy accumulated in the coil L1. This results in the output voltage VO including an unintended noise (voltage drop). -
FIG. 3 is a schematic block circuit diagram of aconventional regulator circuit 200 that includes aDDC circuit 202 and anLDO circuit 204. - The
DDC circuit 202 includes aPWM circuit 210, a pre-driver 212, and an output circuit 214 (transistors T1 and T2). ThePWM circuit 210 includes anerror amplifier 216 and aPWM generator 218. Theerror amplifier 216 and thePWM generator 218 start operating in response to an enable signal DDCEN. ThePWM circuit 210 receives an output voltage VO1 (VO) via a feedback loop FB1 to control the duty cycle of a pulse signal SPWM in accordance with the level of the received output voltage VO1. ThePWM circuit 210 shown inFIG. 3 operates in the same manner as thePWM circuit 102 shown inFIG. 1 . Thus, the operation of thePWM circuit 210 will not be described in detail. - The
LDO circuit 204 includes an output transistor T3,resistors error amplifier 226. Theerror amplifier 226 starts operating in response to an enable signal LDOEN. The output transistor T3 receives a control signal VLDO from theerror amplifier 226 and generates an output voltage VO2 (VO) from an input voltage VIN in response to the received controlled voltage VLDO. The output voltage VO2 is supplied from a feedback loop FB2 to theerror amplifier 226 as a feedback via a node N2 between theresistors error amplifier 226 compares a reference voltage VREF with the feedback voltage of the output voltage VO2. Based on the comparison result, theerror amplifier 226 generates the control voltage VLDO to compensate for fluctuations in the output voltage VO2. - The
regulator circuit 200 selectively operates the DDC circuit 202 (or the PWM circuit 210) and theLDO circuit 204 in accordance with the enable signals DDCEN and LDOEN and generates the output voltage VO in either the PWM mode or the LDO mode. -
FIG. 4 is a schematic waveform chart showing a mode switching operation of theregulator circuit 200 ofFIG. 3 . - When the
LDO circuit 204 is activated in the LDO mode based on a high (H) level enable signal LDOEN, thePWM circuit 210 is deactivated based on a low (L) level enable signal DDCEN. In this case, theregulator circuit 200 outputs the output voltage VO2 that is generated by theLDO circuit 204 as the output voltage VO. - Subsequently, the
PWM circuit 210 starts operating in response to an H level enable signal DDCEN at timing t1. This switches the operation mode of theregulator circuit 200 from the LDO mode to the PWM mode. - When the
PWM circuit 210 begins operating, the coil L1, which is connected to the node N1 of theDDC circuit 202, has not been charged with current energy. Further, theerror amplifier 216 of thePWM circuit 102 has an offset in the same manner as the error amplifier shown inFIG. 1 . Thus, the duty cycle of the pulse signal SPWM is lower than its expected value (the duty increases gradually from zero). As a result, the energy stored in the coil L1 and the offset of theerror amplifier 216 may cause the output voltage VO to include unintended noise (voltage drop). - The invention, together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments together with the accompanying drawings in which:
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FIG. 1 is a schematic block circuit diagram of a conventional regulator circuit (DDC circuit) that includes a PWM circuit and a PFM circuit; -
FIG. 2 is a schematic waveform chart showing a drive sequence of the regulator circuit ofFIG. 1 when the operation mode switches from a PFM mode to a PWM mode; -
FIG. 3 is a schematic block circuit diagram of a conventional regulator circuit that includes a DDC circuit (PWM circuit) and an LDO circuit; -
FIG. 4 is a schematic waveform chart showing a drive sequence of the regulator circuit ofFIG. 3 when the operation mode switches from an LDO mode to a PWM mode; -
FIG. 5 is a schematic block circuit diagram of a regulator circuit (DDC circuit) that includes a PWM circuit and a PFM circuit according to a first embodiment of the present invention; -
FIG. 6 is a schematic block circuit diagram of another PWM circuit (another feed forward circuit) according to the present invention; -
FIG. 7 is a schematic waveform chart showing a drive sequence of the regulator circuit ofFIG. 5 when the operation mode switches from a PFM mode to a PWM mode; -
FIG. 8 is a schematic block circuit diagram of a regulator circuit that includes a DDC circuit and an LDO circuit according to a second embodiment of the present invention; -
FIG. 9A is a schematic waveform chart showing a drive sequence of the regulator circuit ofFIG. 8 when the duty cycle is controlled with an error amplifier and a feed forward circuit before the PWM mode is started; and -
FIG. 9B is a schematic waveform chart showing a drive sequence of the regulator circuit ofFIG. 8 when the duty cycle is controlled with only the feed forward circuit before the PWM mode is started. - In the drawings, like numerals are used for like elements throughout. The present invention provides a circuit and a method for reducing output noise generated when a PWM mode is started.
- One aspect of the present invention is a regulator circuit for generating an output voltage from an input voltage. The regulator circuit includes a pulse width modulation circuit for generating a first pulse signal having a duty cycle that is in accordance with the output voltage. A drive circuit generates the output voltage from the input voltage in response to the first pulse signal provided from the pulse width modulation circuit. A feed forward circuit controls the pulse width modulation circuit to generate the first pulse signal having a duty cycle that maintains the output voltage at a desired level before the pulse width modulation circuit provides the first pulse signal to the drive circuit.
- Another aspect of the present invention is a method for driving a regulator circuit that generates an output voltage from an input voltage. The regulator circuit includes a pulse width modulation circuit for controlling the output voltage with a first pulse signal, a pulse frequency modulation circuit for controlling the output voltage with a second pulse signal, and a feed forward circuit for controlling a duty cycle of the first pulse signal. The method includes activating the pulse frequency modulation circuit, controlling the output voltage with the second pulse signal, activating the feed forward circuit and the pulse width modulation circuit when the pulse frequency modulation circuit is operating, generating the first pulse signal with at least the feed forward circuit until operation of the pulse width modulation circuit is stabilized, and deactivating the pulse frequency modulation circuit after the operation of the pulse width modulation circuit is stabilized.
- A further aspect of the present invention is a method for driving a regulator circuit that generates an output voltage from an input voltage. The regulator circuit includes a low dropout circuit for linearly controlling the output voltage, a pulse width modulation circuit for controlling the output voltage with a first pulse signal, and a feed forward circuit for controlling a duty cycle of the first pulse signal. The method includes activating the low dropout circuit, controlling the output voltage with the low dropout circuit, activating the feed forward circuit and the pulse width modulation circuit when the low dropout circuit is operating, generating the first pulse signal with at least the feed forward circuit until operation of the pulse width modulation circuit is stabilized, and deactivating the low dropout circuit after operation of the pulse width modulation circuit is stabilized.
- Other aspects and advantages of the present invention will become apparent from the following description, taken in conjunction with the accompanying drawings, illustrating by way of example the principles of the invention.
- A regulator circuit according to the present invention will now be described with reference to the drawings.
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FIG. 5 is a schematic block circuit diagram of aregulator circuit 10 according to a first embodiment of the present invention. Theregulator circuit 10 is a DDC circuit including aPFM circuit 12, aPWM circuit 14, a multiplexer (MUX) 16, a pre-driver 18, and anoutput circuit 20. Theoutput circuit 20 includes first and second transistors T1 and T2. In the first embodiment, the first transistor T1 is formed by a P-channel MOS (metal oxide semiconductor) transistor, and the second transistor T2 is formed by an N-channel MOS transistor. The pre-driver 18 and theoutput circuit 20 form adrive circuit 19. A coil (choke coil) L1 has a first terminal, which is connected to a node N1 between the first and second transistors T1 and T2, and a second terminal, which is connected to ground via a capacitor C1. The capacitor C1 is a smoothing capacitor for smoothing output voltage VO that is generated at the second terminal of the coil L1. - The
PWM circuit 14 includes anerror amplifier 26, a feed forward circuit (hereafter referred to as “FF circuit”) 28, asignal processing circuit 30, and aPWM generator 32. Thesignal processing circuit 30 is connected to theerror amplifier 26 and theFF circuit 28. ThePWM generator 32 is connected to thesignal processing circuit 30. Thesignal processing circuit 30 and thePWM generator 32 are activated in response to an enable signal PWMEN. ThePWM circuit 14 compares the output voltage VO with a first reference voltage VREF1 to generate a first pulse signal SPWM having a duty cycle determined in accordance with the comparison result. The structure of thePWM circuit 14 will now be described in detail. - The
error amplifier 26 is supplied with the output voltage VO and the first reference voltage VREF1. The first reference voltage VREF1 corresponds to a target value of the output voltage VO. Theerror amplifier 26 amplifies the voltage difference between the output voltage VO and the first reference voltage VREF1 to generate a control voltage VER for adjusting the duty cycle of the first pulse signal SPWM. More specifically, when the output voltage VO is lower than the first reference voltage VREF1, theerror amplifier 26 increases the control voltage VER in accordance with the voltage difference between the output voltage VO and the first reference voltage VREF1. When the output voltage VO is higher than the first reference voltage VREF1, theerror amplifier 26 decreases the control voltage VER in accordance with the voltage difference between the output voltage VO and the first reference voltage VREF1. Accordingly, theerror amplifier 26 generates the control voltage VER so that the output voltage VO becomes equal to the first reference voltage VREF1. - The
FF circuit 28 controls thePWM circuit 14 to generate the first pulse signal SPWM, which has a duty cycle that maintains the output voltage VO at a predetermined level (or the target value), before thePWM circuit 14 provides the first pulse signal SPWM to thedrive circuit 19. TheFF circuit 28 adjusts the duty cycle of the first pulse signal SPWM, which is generated by thePWM circuit 14, in a manner independent from the control voltage VER, which is generated by theerror amplifier 26. More specifically, theFF circuit 28 generates a feed forward voltage VFF for adjusting the duty cycle of the first pulse signal SPWM using the output voltage VO and input voltage VIN. The first reference voltage VREF1 corresponding to the target value of the output voltage VO may be used instead of the output voltage VO. - The principle of the
FF circuit 28 will now be described briefly. - When the
regulator circuit 10 is controlled based on a duty cycle (duty ratio) DTY of thePWM circuit 14, the output voltage VO is approximated by equation (1), which is shown below. -
VO=VIN*DTY (1) - Thus, the duty cycle DTY is calculated using equation (2), which is shown below.
-
DTY=VO/VIN (2) - Accordingly, the
FF circuit 28 is formed by a divider that calculates the duty cycle DTY using equation (2). The divider (FF circuit 28) divides the output voltage VO by the input voltage VIN and generates the quotient (i.e., duty cycle DTY) as the feed forward voltage VFF. The divider may have any structure. - The
signal processing circuit 30 is supplied with the control voltage VER from theerror amplifier 26 and the feed forward voltage VFF from theFF circuit 28 and provided with a control signal SCONT. Thesignal processing circuit 30 synthesizes the control voltage VER and the feed forward voltage VFF at a predetermined ratio (for example 1:1) in response to the control signal SCONT to generate a duty control voltage VDTY. The feed forward voltage VFF and the control voltage VER may be synthesized at any ratio. The voltages VFF and VER may be weighted with a predetermined coefficient before being synthesized with each other. The control signal SCONT is asserted simultaneously as the enable signal PWMEN. In the first embodiment, the enable signal PWMEN may be used as the control signal SCONT. - The duty control voltage VDTY is supplied to the
PWM generator 32. ThePWM generator 32 compares the duty control signal VDTY with a reference pulse wave (not shown inFIG. 5 ) to generate the first pulse signal SPWM. - The
PFM circuit 12 will now be described. ThePFM circuit 12 includes acomparator 22 and aPFM generator 24, which is connected to thecomparator 22. Thecomparator 22 and thePFM generator 24 are activated based on an enable signal, which is not shown. ThePFM circuit 12 has the same structure as thePFM circuit 104 shown inFIG. 1 . - The
comparator 22 compares the output voltage VO with a second reference voltage VREF2 and generates a comparison signal SCOMP. ThePFM generator 24 selectively generates a second pulse signal SPFM having a substantially constant duty cycle that is determined in accordance with the level of the comparison signal SCOMP, which is provided from thecomparator 22. For example, thePFM generator 24 generates the second pulse signal SPFM only when the output voltage VO is lower than the second reference voltage VREF2. - The
multiplexer 16 is provided with the first pulse signal SPWM, the second pulse signal SPFM, and a mode selection signal SSELECT. In response to the mode selection signal SSELECT, themultiplexer 16 selects one of the first and second pulse signals SPWM and SPFM as a drive pulse signal SDRV. More specifically, the mode selection signal SSELECT is set at a first level in the PWM mode. Themultiplexer 16 selects the first pulse signal SPWM in response to the mode selection signal SSELECT with the first level. The mode selection signal SSELECT is set at a second level in the PFM mode. Themultiplexer 16 selects the second pulse signal SPFM in response to the mode selection signal SSELECT with the second level. - The mode selection signal SSELECT shifts from the second level to the first level based on the enable signal PWMEN. In the first embodiment, the mode selection signal SSELECT shifts from the second level to the first level when a predetermined time elapses after assertion of the enable signal PWMEN. Thus, the operation mode switches from the PFM mode to the PWM mode when the predetermined time elapses after the
PWM circuit 14 is activated. The operation mode switches from the PFM mode to the PWM mode when the duty cycle of the first pulse signal SPWM is stabilized. In other words, the PWM mode is started only after the duty cycle of the first pulse signal SPWM is stabilized. This prevents an unstable drive pulse signal SDRV from being generated when the PWM mode is started. - The drive pulse signal SDRV, which is output from the
multiplexer 16, is provided to the pre-driver 18 of thedrive circuit 19. The pre-driver 18 generates the first and second drive signals VH and VL for driving the first and second transistors T1 and T2 in a complementary manner based on the drive pulse signal SDRV. The first drive signal VH is provided to the gate of the first transistor (PMOS transistor) T1. The second drive signal VL is provided to the gate of the second transistor T2 (NMOS transistor). The source of the first transistor T1 is connected to the input voltage VIN, and the drain of the first transistor T1 is connected to the drain of the second transistor T2. The source of the second transistor T2 is connected to ground. - When the first transistor T1 is activated and the second transistor T2 is deactivated, the current corresponding to the input voltage VIN flows from the node N1 between the transistors T1 and T2 through the coil L1. This charges the coil L1 with energy (current). When the first transistor T1 is deactivated and the second transistor T2 is activated, the energy accumulated in the coil L1 is discharged via a loop formed by the second transistor T2, the coil L1, and the capacitor C1. Accordingly, the coil L1 accumulates energy, the amount of which corresponds to the duty cycle of the drive signal VH (or the drive signal VL). The output voltage VO is changed in accordance with the amount of accumulated energy.
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FIG. 7 is a schematic waveform chart showing a drive sequence of theregulator circuit 10 ofFIG. 5 when the operation mode switches from the PFM mode to the PWM mode. - The
regulator circuit 10 operates in the PFM mode before timing t1. In this mode, only thePFM circuit 12 is activated, and themultiplexer 16 selects the second pulse signal SPFM as the drive pulse SDRV. As a result, the first and second transistors T1 and T2 are driven at a substantially constant duty cycle. - Subsequently, the
PWM circuit 14 is activated based on the enable signal PWMEN at timing t1. ThePWM circuit 14 starts operating and generates the first pulse signal SPWM with the control voltage VER, which is generated by theerror amplifier 26, and the feed forward voltage VFF, which is generated by theFF circuit 28. In this state, the mode selection signal SSELECT is maintained at the second level, which corresponds to the PFM mode. More specifically, the drive pulse signal SDRV, which is output from themultiplexer 16, is maintained as the second pulse signal SPFM. Theregulator circuit 10 continues operating in the PFM mode. - The mode selection signal SSELECT shifts from the second level to the first level at timing t2. The
multiplexer 16 selects the first pulse signal SPWM as the drive pulse signal SDRV in response to the mode selection signal SSELECT, which has the first level. This switches the operation mode of theregulator circuit 10 from the PFM mode to the PWM mode. - As described above, the operation mode switches from the PFM mode to the PWM mode when the duty cycle of the first pulse signal SPWM is stabilized. As a result, when the PWM mode is started (timing t2), the first and second transistors T1 and T2 are driven based on the stabilized first pulse signal SPWM. This prevents the output voltage VO from including unintended noise (voltage drop).
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FIG. 6 is a schematic block circuit diagram of anotherPWM circuit 40 according to the present invention. ThePWM circuit 40 may be used in lieu of thePWM circuit 14 in theregulator circuit 10 shown inFIG. 5 . - The
PWM circuit 40 includes anerror amplifier 26, asignal processing circuit 30, aswitch circuit 42, afilter circuit 44, anintegration circuit 46, anoscillation circuit 47, and acomparison circuit 48. Theoscillation circuit 47 and thecomparison circuit 48 form a PWM generator. Further, theswitch circuit 42, thefilter circuit 44, theintegration circuit 46, theoscillation circuit 47, and thecomparison circuit 48 form a feed forward circuit (FF circuit) 49. Theerror amplifier 26, thesignal processing circuit 30, theoscillation circuit 47, and thecomparison circuit 48 are activated based on an enable signal PWMEN. - The
oscillation circuit 47 generates a sawtooth reference pulse wave VW and provides an inversion input terminal of thecomparison circuit 48 with the reference pulse signal VW. A non-inversion input terminal of thecomparison circuit 48 is supplied with the duty control voltage VDTY, which is generated by thesignal processing circuit 30. Thecomparison circuit 48 compares the duty control signal VDTY with the reference pulse wave VW and changes the duty cycle of the first pulse signal SPWM in accordance with the comparison result. As a result, when the duty control voltage VDTY fluctuates, the duty cycle of the first pulse signal SPWM changes accordingly. - The
switch circuit 42 includes switch elements SW1 and SW2 and aninversion circuit 52. The switch elements SW1 and SW2 are connected to thecomparison circuit 48. Theinversion circuit 52 is connected to a node NA between the switch elements SW1 and SW2. The switch elements SW1 and SW2 are driven in a complementary manner based on the first pulse signal SPWM. For example, the switch element SW1 may be formed by a P-channel MOS transistor, and the switch element SW2 may be formed by an N-channel MOS transistor. Theinversion circuit 52 generates an inverted signal that is obtained by inverting a signal output at the node NA based on the input voltage VIN. Theswitch circuit 42 generates a control pulse signal V1 having the same polarity (the same pulse width) as the first pulse signal SPWM. Theswitch circuit 42 is not limited to the structure shown inFIG. 6 and may have any structure. For example, theswitch circuit 42 may generate a pulse signal of which polarity is opposite to the polarity of the first pulse signal SPWM. - The
filter circuit 44 is a low-pass filter that includes a resistor R1 and a capacitor C2. Thefilter circuit 44 eliminates high-frequency elements from the control pulse signal V1, which is provided from theswitch circuit 42, and generates an adjustment voltage V2, which is substantially a DC voltage. The adjustment voltage V2 is approximated by VIN*DTY (i.e., right-hand side of equation (1)), in which the duty cycle of the first pulse signal SPWM is represented by DTY. - The
integration circuit 46 includes anamplifier 54, a resistor R2, and a capacitor C3. The resistor R2 is connected to an inversion input terminal of theamplifier 54. The capacitor C3 is connected between the inversion input terminal and output terminal of theamplifier 54. The inversion input terminal of theamplifier 54 is supplied with an output voltage VO of theregulator circuit 10 via the resistor R2. A target value of the output voltage VO may be used instead of the output voltage VO. A non-inversion input terminal of theamplifier 54 is supplied with an adjustment voltage V2 1 which is supplied from thefilter circuit 44. Theamplifier 54 compares the adjustment voltage V2 with the output voltage VO. Theamplifier 54 amplifies the difference between the voltages V2 and VO in accordance with the comparison result and generates a feed forward voltage VFF. The feed forward voltage VFF is supplied to thesignal processing circuit 30. Thesignal processing circuit 30 then synthesizes the feed forward voltage VFF with the control voltage VER, which is generated by the feed forward voltage VFF, to generate a duty control voltage VDTY. - The
FF circuit 49 generates the feed forward voltage VFF from the input voltage VIN and the output voltage VO in accordance with the first pulse signal SPWM, which is provided as a feedback via a loop 50 that connects the comparison circuit 48 (pulse generator) and theswitch circuit 42. In detail, theFF circuit 49 generates the feed forward voltage VFF in a manner that the adjustment voltage V2 (i.e., the right-hand side of equation (1), or “VIN*DTY”) becomes equal to the output voltage VO (i.e., the left-hand side of equation (1)). As a result, theFF circuit 49 generates the feed forward voltage VFF more accurately than the FF circuit 28 (divider) shown inFIG. 5 . - The
FF circuit 49 does not necessarily have to use the duty control voltage VDTY, which is supplied from thesignal processing circuit 30. For example, theFF circuit 49 may include another PWM comparison circuit that has the same structure as thecomparison circuit 48. In this case, the PWM comparison circuit receives the feed forward voltage VFF directly from theintegration circuit 46, compares the feed forward voltage VFF with the reference pulse wave VW, and generates the first pulse signal SPWM. With this structure, theFF circuit 49 generates the feed forward voltage VFF in a manner independent from the control voltage VER, which is generated by theerror amplifier 26. This quickly stabilizes the duty cycle of the first pulse signal SPWM. Alternatively, thesignal processing circuit 30 shown inFIG. 6 may select the feed forward voltage VFF as the duty control voltage VDTY. - The
regulator circuit 10 of the first embodiment has the advantages described below. - The
PWM circuit 14 starts operating before the operation mode switches from the PFM mode to the PWM mode. ThePWM circuit 14 generates the first pulse signal SPWM with theerror amplifier 26 and theFF circuit 28 before the PWM mode is started. The PWM mode is then started after the duty cycle of the first pulse signal SPWM is stabilized. Thedrive circuit 19 is then driven based on the first pulse signal SPWM. This prevents the output voltage VO from including unintended noise (voltage drop) that is generated when the PWM mode is started. - The
PWM circuit 14 generates the first pulse signal SPWM with theerror amplifier 26 and theFF circuit 28. This stabilizes the duty cycle of the first pulse signal SPWM more quickly than when theerror amplifier 26 is used solely. As a result, the operation mode quickly switches from the PFM mode to the PWM. - Before the PFM mode is started, the
PWM circuit 14 is driven when thePFM circuit 12 is still being driven. However, thedrive circuit 19 is actually driven by the second pulse signal SPFM until the PWM mode is started. This prevents the first pulse signal SPWM from destabilizing the operation of theregulator circuit 10 in the PFM mode. - The
FF circuit 28 generates the feed forward voltage VFF with the input voltage VIN and the output voltage VO (generated by the PFM circuit 12). Thus, theFF circuit 28 controls the duty cycle in a manner independent from the control voltage VER, which is generated by theerror amplifier 26. - The
PWM generator 32 generates the first pulse signal SPWM with the duty control voltage VDTY, which is generated from the control voltage VER and the feed forward voltage VFF. This accurately control the duty cycle of the first pulse signal SPWM with the control voltage VER and quickly stabilizes the feed forward voltage VFF in the PWM mode. - The
FF circuit 49 inFIG. 6 feedback controls the feed forward voltage VFF with the first pulse signal SPWM. TheFF circuit 49 generates the feed forward voltage VFF more accurately than the FF circuit 28 (FIG. 5 ). -
FIG. 8 is a schematic block circuit diagram of aregulator circuit 60 according to a second embodiment of the present invention. - The
regulator circuit 60 of the second embodiment includes aDDC circuit 62 and anLDO circuit 64. TheDDC circuit 62 includes aPWM circuit 72, a pre-driver 74, and anoutput circuit 20. ThePWM circuit 72 is formed by either thePWM circuit 14 inFIG. 5 or thePWM circuit 40 inFIG. 6 . The pre-driver 74 and theoutput circuit 20 form a drive circuit of the present invention. The drive circuit operates in the same manner as thedrive circuit 19 ofFIG. 5 . - In the PWM mode, the
PWM circuit 72 receives an output voltage VO1 (VO) via a feedback loop FB1 and controls the duty cycle of a first pulse signal SPWM in accordance with the level of the received output voltage VO1. The pre-driver 74 generates drive signals VH and VL based on the first pulse signal SPWM. Transistors T1 and T2 are driven in a complementary manner based on the drive signals VH and VL. As a result, a coil L1 accumulates current energy (current) based on the driving of the transistors T1 and T2. The output voltage VO1 is controlled in accordance with the amount of accumulated energy. - In the second embodiment, the
PWM circuit 72 is activated based on an enable signal PWMEN. The pre-driver 74 is activated based on an enable signal DRVEN. The enable signal DRVEN is associated with the enable signal PWMEN. More specifically, the enable signal DRVEN is asserted when a predetermined time elapses after the enable signal PWMEN is asserted. Thus, the pre-driver 74 is activated when the predetermined time elapses after thePWM circuit 72 is activated. The pre-driver 74 is activated when the duty cycle of the first pulse signal SPWM, which is generated by thePWM circuit 72, stabilizes. Thus, the PWM mode is started only after the duty cycle of the first pulse signal SPWM is stabilized. This prevents unstable drive signals VH and VL from being generated when the PWM mode is started. - The
LDO circuit 64 includes a transistor T3,resistors error amplifier 86. Theerror amplifier 86 starts operating in response to an enable signal LDOEN. The transistor T3 receives a control signal VLDO from theerror amplifier 86 and generates an output voltage VO2 (VO) from an input voltage VIN in response to the received control voltage VLDO. The output voltage VO2 is supplied as a feedback from the feedback loop FB2 to theerror amplifier 86 via a node N2 between theresistors error amplifier 86 compares a reference voltage VREF3 with a feedback voltage of the output voltage VO2 to generate a control voltage VLDO, which compensates for fluctuations in the output voltage VO2 based on the comparison result. - The
regulator circuit 60 selectively operates the DDC circuit 62 (i.e., the PWM circuit 72) and theLDO circuit 64 in accordance with the enable signals PWMEN and LDOEN to generate the output voltage VO in either the PWM mode or the LDO mode. -
FIG. 9A is a schematic waveform chart showing a switching operation of theregulator circuit 60 shown inFIG. 8 from the LDO mode to the PWM mode. - When the
LDO circuit 64 is activated based on an H level enable signal LDOEN in the LDO mode, thePWM circuit 72 is deactivated based on an L level enable signal PWMEN. Thus, theregulator circuit 60 outputs the output voltage VO2, which is generated by theLDO circuit 64, as the output voltage VO. - Subsequently, the enable signal PWMEN shifts to an H level at timing t11. The
PWM circuit 72 starts operating in response to the H level enable signal PWMEN and generates a first pulse signal SPWM based on the control signal VER, which is generated by theerror amplifier 26, and the feed forward voltage VFF, which is generated by the FF circuit 28 (or the FF circuit 49). As a result, the duty cycle of the first pulse signal SPWM increases gradually as thePWM circuit 72 operates. In this case, the enable signal DRVEN is maintained at an L level (the pre-driver 74 is maintained to be deactivated). Thus, theregulator circuit 60 continues operating in the LDO mode. - At timing t12, the enable signal LDOEN shifts to an L level and the enable signal DRVEN shifts to an H level. This deactivates the
LDO circuit 64 and activates the pre-driver 74 of theDDC circuit 62. The enable signal PWMEN is maintained at an H level. Thus, thePWM circuit 72 continues operating. As a result, the operation mode of theregulator circuit 60 switches from the LDO mode to the PWM mode. - As described above, the pre-driver 74 is activated (or the operation mode switches from the LDO mode to the PWM mode) when the duty cycle of the first pulse signal SPWM is stabilized. When the PWM mode is started (at timing t12), the first and second transistors T1 and T2 are driven based on the stabilized first pulse signal SPWM. This significantly reduces output noise (voltage drop) when the LDO mode is switched to the PWM mode.
- The
regulator circuit 60 of the second embodiment has the advantages described below. - The
PWM circuit 72 starts operating before the operation mode switches from the LDO mode to the PWM mode. ThePWM circuit 72 generates the first pulse signal SPWM with theerror amplifier 26 and the FF circuit 28 (FF circuit 49) before the PWM mode is started. The PWM mode is started based on the enable signal DRVEN after the duty cycle of the firs pulse signal SPWM is stabilized. The drive circuit (the pre-driver 74 and the output circuit 20) is then driven based on the first pulse signal SPWM. This significantly reduces output noise generated when the LDO mode is switched to the PWM mode. - The
PWM circuit 72 generates the first pulse signal SPWM with theerror amplifier 26 and the FF circuit 28 (or the FF circuit 49). This stabilizes the duty cycle of the first pulse signal SPWM more quickly than when theerror amplifier 26 is used solely. Accordingly, the operation mode is quickly switched from the LDO mode to the PWM mode. - Before the PWM mode is started, the
PWM circuit 72 is driven when theLDO circuit 64 is still being driven. However, theDDC circuit 62 does not operate (only thePWM circuit 72 operates) until the enable signal DRVEN activates the pre-driver 74. This prevents the first pulse signal SPWM from destabilizing the operation of theregulator circuit 60 in the LDO mode. - It should be apparent to those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or scope of the invention. Particularly, it should be understood that the present invention may be embodied in the following forms.
- The duty control executed by the PWM circuit 14 (
FIG. 5 ) and the PWM circuit 40 (FIG. 6 ) may be changed as shown inFIG. 9B .FIG. 9B is a schematic waveform chart showing a drive sequence of theregulator circuit 60 ofFIG. 8 when the duty cycle is controlled by only the FF circuit (28 or 49) before the PWM mode is started. - The
regulator circuit 60 operates in the LDO mode before timing t11. At timing t11, thePWM circuit 72 starts operating in response to an H level enable signal PWMEN. In this state, thePWM circuit 72 generates a first pulse signal SPWM from only the feed forward voltage VFF. More specifically, thesignal processing circuit 30 selects the feed forward voltage VFF as the duty control voltage VDTY in response to the control signal SCONT having the first level (refer toFIG. 5 orFIG. 6 ). Subsequently, the pre-driver 74 is activated based on the enable signal DRVEN at timing t13, and the PWM mode is started. When a predetermined time elapses after the PWM mode is started, thePWM circuit 72 generates a first pulse signal SPWM with theerror amplifier 26 and theFF circuit 28 or 49 (or generates a first pulse signal SPWM with only the error amplifier 26). More specifically, thesignal processing circuit 30 selects a signal generated by synthesizing the control voltage VER and the feed forward voltage VFF as the duty control voltage VDTY (or selects the control voltage VER as the duty control voltage VDTY) in response to the control signal SCONT having the second level. This generates the first pulse signal SPWM in a manner independent from the output of theerror amplifier 26 before the PWM mode is started. Thus, the operation mode is switched more quickly from the LDO mode to the PWM mode (during t11 to t13) than the control inFIG. 9A . - The
FF circuit 28 may be separate from thePWM circuit 14. - The
FF circuit 49 may be separate from thePWM circuit 40. - The present invention is also applicable to a regulator circuit that operates in one of an LDO mode, a PFM mode, and a PWM mode.
- The present examples and embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein, but may be modified within the scope and equivalence of the appended claims.
Claims (20)
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